Advanced burner systems designed for combustion of recyclable metal powders such as iron and aluminum.
Engineered for stable ignition, controlled combustion, and efficient heat release.
Optimized powder injection and dispersion technology for reliable fuel delivery.
Configurable for laboratory, pilot-scale, demonstration, and practical systems.
Designed for low-emission operation and high combustion efficiency.
Suitable for renewable energy storage and carbon-free heat generation applications.
Design and development of metal powder combustion burners for solid metal-based energy carriers.
Engineering of powder injection systems enabling controlled dispersion and particle transport.
Optimization of burner geometry and flow dynamics to achieve stable combustion regimes.
Control of particle residence time and oxidation kinetics to maximize conversion efficiency.
Integration of advanced combustion diagnostics and temperature measurement systems.
Development of custom laboratory and pilot-scale test rigs for combustion validation.
Implementation of emission reduction strategies including NOx mitigation and particle management.
Support for performance analysis, modeling, and techno-economic evaluation of metal fuel systems.
Enables carbon-free heat generation using recyclable metal fuels.
Converts renewable energy into dispatchable thermal power through metal fuel combustion.
Custom burner solutions tailored to research institutes, energy technology developers, and industrial partners.
Accelerates technology development from concept to validated prototype.
Reduces development risk through structured experimental testing and diagnostics.
Designed for scalability toward pilot and industrial deployment.
Renewable energy storage systems
Iron powder energy cycles
High-temperature industrial heat
Experimental combustion research
Pilot-scale energy conversion systems
Advanced burner systems designed for combustion of recyclable metal powders such as iron and aluminum.
Engineered for stable ignition, controlled combustion, and efficient heat release.
Optimized powder injection and dispersion technology for reliable fuel delivery.
Configurable for laboratory, pilot-scale, demonstration, and practical systems.
Designed for low-emission operation and high combustion efficiency.
Suitable for renewable energy storage and carbon-free heat generation applications.
Design and development of metal powder combustion burners for solid metal-based energy carriers.
Engineering of powder injection systems enabling controlled dispersion and particle transport.
Optimization of burner geometry and flow dynamics to achieve stable combustion regimes.
Control of particle residence time and oxidation kinetics to maximize conversion efficiency.
Integration of advanced combustion diagnostics and temperature measurement systems.
Development of custom laboratory and pilot-scale test rigs for combustion validation.
Implementation of emission reduction strategies including NOx mitigation and particle management.
Support for performance analysis, modeling, and techno-economic evaluation of metal fuel systems.
Enables carbon-free heat generation using recyclable metal fuels.
Converts renewable energy into dispatchable thermal power through metal fuel combustion.
Custom burner solutions tailored to research institutes, energy technology developers, and industrial partners.
Accelerates technology development from concept to validated prototype.
Reduces development risk through structured experimental testing and diagnostics.
Designed for scalability toward pilot and industrial deployment.
Renewable energy storage systems
Iron powder energy cycles
High-temperature industrial heat
Experimental combustion research
Pilot-scale energy conversion systems
